KR820002401B1 - Pick up tube - Google Patents

Abstract

This is a pick-up tube equipped with electron gun which need not suffer from additional calbration, because shaft of the gun is in accord with a central line of electron beam. It has the characteristic that cathode(23) consists of cathode electrode(24), whose surface has electron mission layer(25) , which is fixed to isolation material(27) by upholders(27). The material927) is fixed to bush(28) which has flange(29) fixed to anode(30). The advantage of the structure is the feasibility to weld bush to anode as located in accord with shaft of gun. This si because the bush can be moved perpendicularly to the shaft before it is welded to anode.

Description

An imaging tube

1 is a partial cross-sectional view of a gun according to the prior art.

2 is a partial cross-sectional view of a conventional two-pole electron gun.

3 is a partial cross-sectional view of a two-pole electron gun for scratch tubes according to the present invention.

4 is a partial cross-sectional view of a second embodiment of a two-pole electron gun for scratch tube according to the present invention.

5, 6, and 7 are longitudinal cross-sectional views and plan views, respectively, showing the process of the method for manufacturing a two-pole electron gun.

8 is a cross-sectional view of the scratch tube of the present invention.

The present invention is directed to sequentially placing a cathode having an electron emitting surface located at least on an axis and extending substantially perpendicular to the axis, and an electrode having a central hole blocked by a perforation plate at a portion extending perpendicular to the axis. And electrically insulate and fix the cathode to the metal bushing for supporting the cathode, and at the same time the portion extending at right angles to the axis of the cathode supporting metal bush is disposed opposite to the axis of the electrode. It relates to an image pickup tube provided with an electron gun fixed by fixing to one end of a cylindrical vacuum.

The present invention also conduits the above-described method for producing an imaging tube.

This kind of imaging tube is widely applied to fields such as television cameras and infrared cameras, for example.

However, the above-described type of electron gun is described in the January 1978 issue of "Radio Technology" magazine, in which a cathode (cathode) connected to a cathode support bush by a plug of insulating material is shown. . In addition, the support bush for the cathode support is fixed to the first grid. The first grid has a central circular hole in which the cathode support bush is centered by a coaxial groove. However, such a structure is very inaccurate for use in television cameras equipped with a two-pole electron gun, so that the cathode is often attached to the cathode support bush as an inconsistent center and also inclined. If this is corrected, the correction is already impossible. Imaging tubes as described above, in particular bipolar electron guns, are described in US Pat. No. 3,854,262. However, nothing is described here about the structure, positioning and connection of the cathode, the cathode support bush and the anode (anode). In addition to the two-pole electron gun, this type of imaging tube has a connecting lens for connecting the generated electron beam to the photoconductive layer formed on the signal electrode, and the potential distribution in the tube rises at the position of the photoconductive layer when the incident image is projected onto the photoconductive layer. do. By scanning the electron beam on the photoconductive layer, an electrical signal corresponding to incident light appears on the signal electrode. Formation of the electron beam and scanning of the electron beam cause various problems in the case of a small imaging tube.

For example, if the center line of the electron beam through the hole of the anode plate is at an angle of 1 degree to the axis of the electron gun, the amount of electron beam incident on the photoconductive layer, that is, the beam current, is reduced by about 25%. Throw it away. The electron gun of the above-described structure described in the January 1978 issue of the Radio Technology magazine is essentially impossible to align the axis of the electron gun with the centerline of the electron beam during its assembly, so this mismatch must be corrected by another calibration coil. It is not preferable for use in an imaging tube.

The object of the present invention is to solve the above-mentioned seed problem. SUMMARY OF THE INVENTION An object of the present invention is to provide an imaging tube having an electron gun having a structure in which the axis of the electron gun and the center line of the electron beam can be easily and easily aligned, and there is no need to provide any other calibration means.

Imaging tubes of the present invention of the kind described in the preamble include the electron emitting surface when the electron gun is a two-pole electron gun in which the electrode forms an anode, and the anode and the cathode support metal bush are not connected to each other. It is characterized in that the portion of the anode extending at right angles to the axis can be moved at right angles to the axis relatively in a state of maintaining exactly parallel to each other.

In the electron gun in the form of a two-pole electron gun, the relative position in the direction perpendicular to the axis of the electron emitting surface is not very important, but very important in the two-pole electron gun. In the two-pole electron gun having the structure according to the present invention, it is easy to match the axis of the electron gun and the center of the electron beam by fitting the center of the electron emitting surface to the hole center of the anode electrode tube. Since it can be made small compared with the conventional one, therefore, the anode loss can be significantly reduced.

In the two-pole electron gun according to the present invention, it is preferable to provide a flange extending inward to the metal bush for the cathode support to increase the space that can be used for assembling the cathode into the metal bush. In addition, by installing a cylindrical surface parallel to the side of the electron gun that matches the inner wall of the glass tube shell and at the same time surrounding the cathode support bush, the shaft alignment between the two-pole electron gun and the cylindrical tube according to the present invention can be easily and easily performed. I can do it. In addition, if the surface extending at right angles to the electron gun axis and the electron emitting surface are disposed on the same plane to be located at the anode of the cathode support bush, the distance between the anode and the cathode can be sufficiently determined by the shape pipe of the anode.

As described above, disposing the surface of the negative electrode support metal bush and the electron emitting surface fixed on the anode in the same plane is almost equiaxed in the negative electrode support metal bush as described below for the embodiment of the present invention. A cathode supporting metal is fixed by two projections formed on the cathode supporting metal bush while the cathode is fixed in the supporting metal bush by the insulating disk located thereon. This can be achieved simply by locking in the bush.

According to the present invention, a method of manufacturing an image tube includes fixing a cathode tube cathode support metal bush on an electron emission surface of the cathode and an anode surface of the cathode support metal bush on a parallel plane or on the same plane and then fixing them to each other. Then, the negative electrode support metal bush is disposed opposite to the portion extending perpendicularly to the electron gun axis of the positive electrode, and then the negative electrode support metal bush is moved perpendicularly to the electron gun axis relative to the positive electrode. Align the center hole center of the anode at the center of the electron-emitting surface, and then connect the metal support plate for the cathode to the anode, and then adjust the hole center ratio of the cathode plate to the center of the electron-emitting surface, and fix the anode plate to the anode. It is characterized by making an electron gun by attaching it.

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

FIG. 1 is a view showing a part of a conventional electron gun structure. The conventional gun gun has a cathode 1 having a heating element 2 provided inside the cathode electrode 3 and an electron emission layer 4 provided on the surface thereof. Equipped. The cathode 1 is fixed to the bushing 7 for supporting the negative electrode by an insulating plug 5 and a bush 6. The cathode support bush 7 has flanges 8 extending outwardly at right angles from its cylindrical surface and annular centering groove 9. As a result of the centering by the annular flaws 9, the cathode support bush 7 and the anode are fixed relative to each other in the direction perpendicular to the electron axis. The flange 8 is welded to the first grid 10 having the center hole 11, and the center hole 11 is blocked by the electrode plate 13 having the hole 12. The drawback of this structure is that the assembly of the cathode 1 in the support bush 7 is inaccurate, and as a result often the electron emitting surface 4 is tilted and out of center with the hole 12 of the electrode plate 13. In addition, the center of the cathode 1 deviates from the axis of the first grid electrode 10. Therefore, this conventional structure is inadequate for a two-pole electron gun in which the electron gun axis and the centerline of the generated electron beam must be exactly matched.

Next, FIG. 2 shows the structure of a conventional two-pole electron gun, in which the cathode 15 having the heating member 16 is located in the cathode support bush 14. The cathode support bush 14 has a hole 17.

An anode 18 having a circular central hole 19 is provided opposite the cathode 15, and the central hole 19 is blocked by an anode wood plate 20 having a hole 21. As shown in FIG. The problem with the two-pole electron gun of this structure is that the parts are fixed to each other after fixing the positions of the centers of the electron emission surfaces 22 and the centers of the holes 21 of the anode electrode plate 20. When you fix it, you may get out of the pre-set center position.

An embodiment of a two-pole electron gun for an imaging tube according to the present invention is shown in FIG. The cathode 23 is composed of a cathode electrode 24 incorporating a heating member (not shown). The cathode electrode 24 has an electron emission layer 25 on the surface thereof, It is fixed to the disc 27 of the heat insulating material.

The heat insulating material 27 is fixed in the anode support bush 28 having the flange 29 extending inward at right angles to the shaft, the flange 29 is fixed to the anode wood 30 and the anode wood is It has a circular shape and a center hole 31, and the center hole 31 has a hole 33 and is partially blocked by the electrode plate 32 fixed to the anode 30.

The advantage of this structure is that the cathode support bush with the inner cathode attached can be moved at right angles to the axis until welded to the anode, so that the center of the electron emitting layer, the center of the circular center hole of the anode and the electrode plate described above The ohmic pole bush can be anodized with the hole center exactly positioned on the same axis, the electron gun axis.

Next, another embodiment of a two-pole electron gun in the imaging tube of the present invention is shown in FIG. 4, in which the cathode 34 blocks an end and installs an electron emission layer 36 on the other end. It consists of a cylindrical cathode electrode 35 provided with a heating member 44.

The cylindrical cathode electrode 35 is connected to the metal bush 38 by a few pieces of metal 37, and the metal bush 38 is fixed to the insulating plate 39. Since the outer circumferential surface 40 of the insulating plate 39 has a convex surface shape, the outer peripheral surface 40 may be inclined at an arbitrary angle in the bushing 41 for the negative electrode support, and the bush after adjusting to an appropriate angle as described below. It is fixed to the bushing 41 for a cathode support by the three protrusion part 42 provided in 41. As shown in FIG. That is, by inclining the insulating plate 39 of an insulating material at an appropriate angle as described above, the flange 43 and the electron emitting surface 36 of the cathode 34 and the inner side of the cathode support bush 41 and Can be located very simply and exactly on the same plane.

The cathode support bush 41 assembled as described above allows the center of the electron emission layer 36 and the center of the circular center hole 46 of the anode 45 to be positioned on the same electron gun axis. 45). The anode 45 also has an anode plate 47 having a hole 48 located on the electron gun axis.

A preferred manufacturing method for the bipolar electronic layer of the above-described structure in the television imaging tube according to the present invention will be described in more detail with reference to FIGS. 5, 6 and 7.

FIG. 5 shows a state in which the cathode 49 is assembled into the cathode support bush 50. The flange 52 of the electron-emitting layer 51 and the cathode support bush 50 has a transparent plane 53 ) Is pressed tightly. As a result, the electron emission layer 51 and the flange 52 are located on the same flat surface. At this time, whether or not the electron-emitting layer 51 is completely in contact with the surface of the flat tube 53 can be seen through the transparent flat plate 53. In addition, the flange 52 of the cathode support bush 50 on the two parallel pieces defined by such a step-by-step molding mold, using a molding frame that is adjusted in stages instead of pressing firmly to the single flat plate as described above. And the electron emission layer 51 may be positioned respectively.

Subsequently, the insulating plate 54 is fixed to the cathode support bush 50 by the projections 42 shown in FIGS. 4 and 6. At this time, the cathode support bush 50 together with the cathode 49 is disposed in the anode 55 as shown in FIG. By moving the cathode support bush 50 and the anode 55 relatively at right angles to the axis, the center of the electron emission layer 51 and the center of the center hole 56 of the anode 55 face each other. Is placed. At this time, by welding the cathode support bush 50 and fixed to each other. And as shown in FIG. 7, when the microscope which provided the straight line 58 and the center cross hair 57 to the focusing surface is used, the above-mentioned center position adjustment is performed very correctly and correctly.

The electron-emitting surface 51 as shown in FIG. 7 is equiaxed down the augmentation hole 56 of the anode 55 by moving the cathode support bush relative to the anode 55. Second. The central solid line 57 sets the center of the electron emitting surface 51 and the central hole 56. At this time, the hole center of the anode electrode tube is positioned by the cross hairs 57, and then the anode electrode plate is welded to the anode.

An imaging tube according to the present invention is shown in FIG. This imaging tube is provided with the glass shell 59 obtained by the suction of the glass tube with respect to a core rod. The glass shell 59 is in the form of a staircase.

A two-pole electron gun as shown in FIG. 4 is provided at one end of the glass envelope. The anode 45 is mass fired on the shoulder 60 in the glass skin tube. The electrode 61 is provided on the inner wall of the glass envelope. In addition, the imaging tube includes a diaphragm 62, a mesh electrode 63, and a window 64 having a photoconductive layer 65 inside.

As apparent from the foregoing, the use of the two-pole electron gun having the structure according to the present invention makes it easy to match the axes of the electron gun, the glass envelope and the generated electron beam in the image pickup tube. The calibration coil required by the imaging tube can be removed.

Claims (1)

A cathode having an electron-emitting surface positioned at least on an axis and extending substantially perpendicular to the axis, and an electrode having a central hole blocked by a perforated plate at a portion extending at right angles to the axis; A cylindrical vacuum jacket was used to electrically insulate and fix the metal gun to the portion extending at right angles to the axis of the cathode support metal bush. The electron gun was fixed to the portion extending at right angles to the axis of the electrode. In an imaging tube positioned at one end of The electron gun is a two-pole electron gun in which the electrode is an anode, and the cathode support metal bush having a flange extending inwardly perpendicular to the anode and in the inward direction is not connected to each other in the state where the electron emitting surface is not connected to each other. And the portion extending at right angles to the axis of the anode can be moved at right angles to the axis while keeping the parts parallel to each other exactly.

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